JP3827876B2 - Radiation image data acquisition method and apparatus, and radiation solid state detector - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a radiation solid state detector, in particular, a radiation image data acquisition method and apparatus for acquiring an image signal representing radiation image information from a detector having a stripe electrode, and a radiation solid state detector used therefor.
[0002]
[Prior art]
Today, in radiography for medical diagnosis and the like, a radiation image recording / reading apparatus using a radiation solid detector (mainly a semiconductor) that detects radiation and outputs an image signal representing radiation image information. It has been known. Various types of detectors used in this apparatus have been proposed and put to practical use.
[0003]
For example, from the aspect of the charge generation process that converts radiation into electric charge, the signal charge obtained by detecting the fluorescence emitted from the phosphor by irradiation with the radiation by the photoelectric conversion element is stored in the power storage unit of the photoelectric conversion element. A light conversion type radiation solid state detector (for example, Japanese Patent Laid-Open No. 59-211263, Japanese Patent Laid-Open No. 2-164067, PCT International Publication No. WO92 /) which once accumulates and converts the stored charge into an image signal (electrical signal) and outputs it. 06501, SPIE Vol.1443 Medical Imaging V; Image Physics (1991), p.108-119, etc.), or collecting signal charges generated in a radiation conductor by irradiation with a charge collecting electrode for storage A direct-conversion radiation solid-state detector that temporarily accumulates in the unit and converts the stored charge into an electrical signal and outputs it (MATERIAL PARAMETERS IN THICK HYDROGENATED AMORPHOUS SILICON RADIATION DETECTORS, Lawrence Berkeley Laboratory. University of California, Berkeley.CA 94720 Xerox Parc .Pa lo Alto. CA 94304, Metal / Amorphous Silicon Multilayer Radiation Detectors, IEE TRANSACTIONS ON NUCLEAR SCIENCE. VOL. 36. NO.
[0004]
In addition, from the aspect of a charge reading process for reading out the accumulated charge to the outside, a TFT reading type reading and reading light (reading electromagnetic wave) that scans and drives a TFT (thin film transistor) connected to the power storage unit. There is an optical readout type that reads out by irradiating a detector.
[0005]
The applicant of the present application has proposed an improved direct conversion radiation solid state detector in Japanese Patent Application Nos. 10-232824 and 10-271374. The improved direct conversion type radiation solid state detector is a direct conversion type and optical readout type, and has a first conductor layer having transparency to recording radiation, and the first conductor. The recording photoconductive layer that exhibits photoconductivity (exactly radiation conductivity) by being irradiated with the recording radiation that has passed through the layer has a charge of the same polarity as the charge charged on the first conductor layer. On the other hand, it acts as a substantially insulator, and a charge transport layer that acts as a conductor for charges having a polarity opposite to that of the charge. A recording photoconductive layer and a charge transport layer, which are formed by laminating a reading photoconductive layer exhibiting (electromagnetic conductivity) and a second conductive layer transparent to the reading electromagnetic wave in this order. Signal charge (latent image charge) carrying image information at the interface (power storage unit) It is intended to accumulate. The first conductor layer and the second conductor layer function as electrodes. The solid-state detection element in this system has a recording photoconductive layer, a charge transport layer, and a reading photoconductive layer as main parts.
[0006]
Further, in the optical readout system including this improved direct conversion system, as a system for reading out the signal charges accumulated in the power storage unit, for example, a second conductor layer (hereinafter referred to as an electrode on the side irradiated with the readout light) (Reading electrode) is a flat plate and scans spot-like reading light such as laser on the reading electrode side to detect the signal charge, or the reading electrode is arranged in a comb-like shape. The striped electrodes are formed in such a manner that the longitudinal direction of the stripe electrodes, that is, the direction substantially perpendicular to the longitudinal direction of each linear electrode is the main scanning direction, and the longitudinal direction is the sub-scanning direction. 3 to detect the signal charge by scanning the line light source extending in the main scanning direction in the longitudinal direction of the stripe electrode (that is, the sub-scanning direction). There is a method.
[0007]
[Problems to be solved by the invention]
However, in the optical readout type detector, when the charge stored in the power storage unit is read, not only the current corresponding to the amount of charge stored in the power storage unit corresponding to the portion irradiated with the reading light but also the above-mentioned correspondence There is a problem that dark current flows in accordance with the amount of electric charge accumulated in the vicinity of the power storage unit or in the entire power storage unit. In addition, in a detector in which the reading electrode is a stripe electrode, there is a problem that dark current flows into the linear electrode from a pixel portion other than the target pixel portion irradiated with the reading light in the longitudinal direction of the linear electrode. That is, in an optical readout type detector including those having stripe electrodes, the image signal output from the detector includes a dark current component in addition to the original image signal component, and is based on the output image signal. The reproduced output image is offset by dark current and the density is increased. Especially in the case of having a stripe electrode, the dark current component of the entire longitudinal direction is added to the signal of the target pixel portion. This problem appears remarkably.
[0008]
The present invention has been made in view of the above problems, and a radiation image data acquisition method for correcting an image signal so as to reduce a dark current component contained in an image signal output from a light readout type detector, and The present invention relates to an apparatus and a radiation solid detector used therefor.
[0009]
[Means for Solving the Problems]
A radiation image data acquisition method according to the present invention includes a power storage unit that stores an amount of electric charge according to the dose of irradiated radiation, and a stripe electrode composed of a plurality of linear electrodes stacked on the power storage unit. A radiation image data acquisition method for acquiring an image signal representing radiation image information from the radiation solid detector using an optical readout solid state detector,
As a radiation solid state detector, use one in which an insensitive part insensitive to radiation is formed in a part corresponding to a part of the stripe electrode in the longitudinal direction,
In the longitudinal direction of the stripe electrode in the image signal, components other than the insensitive part are corrected so that the dark current component included in the image signal is reduced for each linear electrode based on the insensitive part component. And
[0010]
The “striped electrode” means an electrode formed by forming the plurality of linear electrodes in a comb shape. The “longitudinal direction of the stripe electrode” means the longitudinal direction of the linear electrode.
[0011]
When forming the “insensitive part insensitive to radiation” on the detector, instead of providing a photoconductive layer in the part where the recording photoconductive layer is laminated in the part where the insensitive part is to be provided, A member having no sensitivity may be provided so as not to have any sensitivity to radiation, or the recording conductor layer in that portion is covered with a member having high radiation absorption such as lead, and the recording photoconductive layer is covered. Even if the recording radiation is not irradiated to the layer at all, or a minute amount of radiation is irradiated, the charge corresponding to the radiation dose may not be accumulated in the power storage unit. .
[0012]
“Correction of components other than the insensitive part based on the components of the insensitive part so that the dark current component included in the image signal is reduced” means that the image signal including the dark current component is applied to the part other than the insensitive part. It means to reduce the dark current component, for example, it is not limited to reducing the dark current component included in the image signal by subtracting the component of the insensitive part from the component other than the insensitive part, Various calculation processes are performed based on the components of the insensitive part, and as a result, any correction can be made as long as the dark current component can be reduced from the image signal including the dark current component for the part other than the insensitive part. A method may be used.
[0013]
Note that “subtracting the component of the insensitive part from the component other than the insensitive part” means subtracting the component of the image signal corresponding to the insensitive part, that is, the insensitive part signal itself from the component of the image signal corresponding to the part other than the insensitive part. The correction signal for each position other than the insensitive part in the longitudinal direction of the stripe electrode is obtained based on the insensitive part signal, and the correction signal is regarded as a component of the insensitive part for each position. It also includes subtracting the obtained correction signal from the component of the image signal corresponding to the part other than the insensitive part.
[0014]
In the radiological image data acquisition method according to the present invention described above, an image signal radiation solid detector is provided in an area outside the image area in the longitudinal direction of the stripe electrode so as not to cause a defect in the radiographic image information obtained by providing the insensitive part. It is preferable to use one provided with an insensitive part. Here, the “image region” is a region where a desired radiographic image is normally captured, and means a region on a detector for accumulating charges representing radiographic image information.
[0015]
In the radiation image data acquisition method according to the present invention, a radiation solid state detector having an insensitive part at one end of the stripe electrode can be used.
[0016]
Furthermore, in the radiation image data acquisition method according to the present invention, a radiation solid state detector having a non-sensitive portion provided at both ends of the stripe electrode is used, and each insensitive provided at both ends of the image signal is used. A correction component for the image signal at each position other than the insensitive portion in the longitudinal direction of the stripe electrode may be obtained based on the component of the stripe electrode, and the correction may be performed based on the obtained correction component.
[0017]
In addition, as a radiation solid state detector, one in which a non-sensitive portion is provided only on a part of the linear electrodes of the stripe electrode is used, and a linear electrode not provided with a non-sensitive portion is insensitive in the longitudinal direction of the stripe electrode. A correction component for the image signal at each position other than the portion may be obtained, and the obtained correction component may be subtracted from the component other than the insensitive portion in the image signal.
[0018]
Furthermore, the radiation solid state detector includes a linear electrode provided with a dead part at one end of the stripe electrode and a linear electrode provided with a dead part at the other end, that is, a striped electrode. A stripe electrode having a dead portion at one end and a linear electrode having no dead portion at either end while using a detector having a dead portion at one end of each For the electrodes (that is, for all linear electrodes), the longitudinal direction of the stripe electrode based on the component of the insensitive part provided at one end of the linear electrode and the component of the insensitive part provided at the other end The correction component for the image signal at each position other than the insensitive portion may be obtained, and the obtained correction component may be subtracted from the component other than the insensitive portion in the image signal.
[0019]
When using a detector in which one of the stripe electrodes is provided with an insensitive portion at one end of the other, it is more preferable to arrange the one and the other alternately. Although “alternate” is used, it is not limited to each linear electrode, and the one and the other may be alternately arranged every several lines.
[0020]
Further, in the radiation image data acquisition method according to the present invention, an image signal for a part of the plurality of linear electrodes arranged in a row is acquired at one end of the stripe electrode, and the rest It is desirable to acquire the image signal for the linear electrode at the other end of the stripe electrode.
[0021]
“A plurality of linear electrodes arranged in a row” is not limited to two linear electrodes adjacent to each other, but may be three or more linear electrodes arranged in a row.
[0022]
“Acquisition of image signals for some linear electrodes at one end of the stripe electrode and acquisition of image signals for the remaining linear electrodes at the other end of the stripe electrode” means every other line. Or, every several lines means that the one end and the other end are staggered to obtain an image signal for each linear electrode. For example, when acquiring image signals for four linear electrodes, the right two are acquired at one end of the stripe electrode, and the remaining two left are acquired at the other end of the stripe electrode. Etc.
[0023]
In addition, when there are a large number of linear electrodes, such as 100, provided on the detector, the above-described “sequentially arranged linear electrodes” may be repeatedly applied sequentially. In other words, the image signal for each linear electrode may be acquired by alternately staggering the one end and the other end every other linear electrode or every few.
[0024]
The radiation image data acquisition apparatus according to the present invention is an apparatus that realizes the above method, that is, a power storage unit that accumulates an amount of electric charge according to the dose of irradiated radiation, and a plurality of linear shapes stacked on the power storage unit. Radiation image data comprising a radiation solid state detector comprising a stripe electrode comprising electrodes and a reading means for obtaining an image signal representing radiation image information by scanning the reading light in the longitudinal direction of the stripe electrode An acquisition device,
The radiation solid detector is a portion insensitive to radiation formed in a portion corresponding to a part of the stripe electrode,
Dark current reduction that corrects components other than the insensitive part so that the dark current component included in the image signal is reduced for each stripe electrode in the longitudinal direction of the stripe electrode in the image signal based on the component of the insensitive part. Means are provided.
[0025]
The radiological image data acquisition apparatus according to the present invention is a radiation solid detector, in which insensitive portions are provided at both ends of the stripe electrode,
The dark current reducing means obtains a correction component for the image signal at each position other than the insensitive portion in the longitudinal direction of the stripe electrode based on the insensitive portion components provided at both ends of the image signal, and the obtained correction. The correction may be performed based on the component.
[0026]
Further, the radiation solid state detector is assumed to be provided with insensitive portions only in some linear electrodes of the stripe electrode,
For the linear electrode not provided with the insensitive part, the dark current reducing means other than the insensitive part in the longitudinal direction of the stripe electrode based on the component of the insensitive part of the linear electrode provided with the insensitive part of the image signal It is also possible to obtain a correction component for the image signal at each position.
[0027]
The radiation solid state detector includes a linear electrode provided with an insensitive part at one end of the stripe electrode and a linear electrode provided with an insensitive part at the other end,
The dark current reducing means is provided for the stripe electrode having the insensitive portion and the linear electrode not provided with the insensitive portion, the component of the insensitive portion provided at one end of the linear electrode and the other end. A correction component for the image signal at each position other than the insensitive portion in the longitudinal direction of the stripe electrode can be obtained based on the component of the insensitive portion, and the correction component can be subtracted from the component other than the insensitive portion of the image signal.
[0028]
In the radiological image data acquisition apparatus according to the present invention, the reading means transmits an image signal for a part of the plurality of linear electrodes arranged in a row at one end of the stripe electrode. It is desirable that the image signal for the remaining linear electrodes among the plurality of linear electrodes that are acquired and continuously arranged be acquired at the other end of the stripe electrode. For example, when a method of detecting a signal charge by scanning a line light source in the longitudinal direction of the stripe electrode, the one end and the other end are provided every other or several linear electrodes. It is preferable that the current detection amplifiers are connected to the one end or the other end of each linear electrode by repeating the above.
[0029]
A radiation solid state detector according to the present invention includes a detector used in the above method and apparatus, that is, a power storage unit that accumulates an amount of electric charge according to the dose of irradiated radiation, and a plurality of layers stacked on the power storage unit. A radiation solid-state detector comprising a stripe electrode made of a linear electrode, wherein a non-sensitive portion insensitive to radiation is formed in a portion corresponding to a part of the stripe electrode. To do.
[0030]
In the radiation solid detector according to the present invention, it is desirable that an insensitive portion is provided in a region outside a desired image region in the longitudinal direction of the stripe electrode.
[0031]
The insensitive part may be provided at one end or both ends of the stripe electrode.
[0032]
The radiation solid state detector according to the present invention includes a linear electrode provided with a dead part at one end of the stripe electrode and a linear electrode provided with a dead part at the other end. You can also.
[0033]
Furthermore, the radiation solid-state detector according to the present invention is connected to one end of the stripe electrode for acquiring an image signal of a part of the plurality of linear electrodes arranged in a row. A current detection amplifier and a current detection amplifier connected to the other end of the stripe electrode for acquiring an image signal of the remaining linear electrodes among the plurality of linear electrodes arranged in series Is desirable.
[0034]
【The invention's effect】
According to the radiation image data acquisition method and apparatus of the present invention, the radiation solid-state detector is sensitive to radiation at a part of the stripe electrode in the longitudinal direction, for example, one end part or both end parts outside the image area. The dark current component included in the image signal is reduced based on the component of the insensitive part of the image signal or the correction component obtained based on the component of the insensitive part. As described above, the components other than the insensitive portion are corrected, so that an image reproduced and output based on the image signal with the dark current component reduced does not cause an offset due to the dark current, and an image having an appropriate density is obtained. Obtainable.
[0035]
Even if the insensitive part is not provided for every linear electrode, the correction component is also applied to the linear electrode without the insensitive part based on the insensitive part component of the linear electrode with the insensitive part provided. Since the insensitive portion can be provided so as not to affect the image region as much as possible, it is convenient.
[0036]
In addition, every other or every several linear electrodes, one end and the other end of the stripe electrode are alternately staggered, and the current detection amplifier is connected to the one end or the other end of each linear electrode. For example, the image signal for a part of the plurality of linear electrodes arranged in a row is acquired at one end of the stripe electrode, and the remaining linear electrodes are connected. If the image signal is acquired at the other end, the correction component for the image signal at each position other than the insensitive portion in the longitudinal direction of the stripe electrode is obtained using the insensitive portion component of the adjacent linear electrode. Therefore, the variation factor of the dark current component at each position in the longitudinal direction due to the line resistance of the linear electrode can be corrected. In addition, the current detection amplifiers constituting the reading means are not concentrated on one side of the stripe electrode, but can be arranged substantially equally in the area in the vicinity of one end and the other end. This is also convenient in integrating the current detection amplifier with the detector.
[0037]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. 1A and 1B are schematic views of a radiographic image reading / reading apparatus to which a radiographic image data acquisition method and apparatus according to the present invention are applied. FIG. 1A is a perspective view, and FIG. 1B is an XZ cross section of a detector. FIG. 1C is an XY cross-sectional view. In FIG. 1A, a part of a recording device (power source or the like) for recording an electrostatic latent image on the detector 10, a light source control means 40 for controlling the reading planar light source 30, and a current detection circuit 50 are also shown. Show. As shown in FIG. 1, the radiographic imaging reader 1 controls a radiation solid state detector 10, a planar light source 30 stacked on the detector 10 for reading out electric charges from the detector 10, and the planar light source 30. And a reading unit 20 including a current detection circuit 50.
[0038]
The detector 10 records radiation image information as an electrostatic latent image, and generates a current corresponding to the electrostatic latent image by being scanned with an electromagnetic wave for reading (hereinafter referred to as reading light). Specifically, the first conductor layer 11 having transparency to recording radiation (for example, X-ray or the like; hereinafter referred to as recording light), exhibits conductivity by being irradiated with the recording light. The recording photoconductive layer 12 and the charge on the conductive layer 11 (latent image polar charge; for example, negative charge) act as an insulator and have a charge opposite to the charge (transport polar charge). A positive charge) in the above-described example, a charge transport layer 13 that substantially acts as a conductor, a reading photoconductive layer 14 that exhibits conductivity when irradiated with reading light, and is transparent to reading light. The second conductor layer 15 having Is (see electrostatic recording material as claimed Japanese Patent Application No. 10-232824). The conductor layer 15 as a reading electrode is formed by arranging a large number of linear electrodes (shaded portions in the figure) in a comb shape. Hereinafter, the conductor layer 15 is referred to as a stripe electrode 15, and each linear electrode is referred to as an element 15a (element numbers e1 to en).
[0039]
The planar light source 30 is an EL luminous body composed of a conductive layer 31, an EL layer 32, and a conductive layer 33, and is stacked on the detector 10 as described above. An insulating layer 34 is provided between the stripe electrode 15 of the detector 10 and the conductive layer 31. The conductive layer 31 is formed in a comb-like shape so as to intersect with each element 15a of the stripe electrode 15 of the detector 10 (substantially orthogonal in this example). A large number of linear light sources are arranged in a plane. Each comb tooth 31 a is connected to the light source control means 40. Each comb tooth 31 a is formed of a material transparent to the EL light from the EL layer 32. The wavelength of the EL light emitted from the EL layer 32 is a wavelength suitable for reading the electrostatic latent image from the detector 10.
[0040]
The light source control means 40 applies a predetermined voltage to the comb teeth 31a individually between the comb teeth 31a and the conductive layer 33 facing the comb teeth 31a. When a predetermined DC voltage is applied between the comb teeth 31a and the conductive layer 33 while sequentially switching the comb teeth 31a, EL light is emitted from the EL layer 32 sandwiched between the comb teeth 31a and the conductive layer 33. The EL light transmitted through the comb teeth 31a is used as line-shaped reading light (hereinafter referred to as line light). In other words, the planar light source 30 is equivalent to a large number of line-shaped micro light sources arranged in a planar shape, and the comb teeth 31a are sequentially switched from one end to the other end of the stripe electrode 15 in the longitudinal direction. By EL emission, the entire surface of the stripe electrode 15 is electrically scanned with line light.
[0041]
The current detection circuit 50 has a large number of current detection amplifiers 51 connected to the inverting input terminal for each element 15 a of the stripe electrode 15. The conductor layer 11 of the detector 10 is connected to one input of the connection means 52 and the negative electrode of the power supply 53, and the positive electrode of the power supply 53 is connected to the other input of the connection means 52. Although not shown, the output of the connection means 52 is connected to the non-inverting input terminal of each current detection amplifier 51. When the line light as the reading light is exposed to the stripe electrode 15 side from the planar light source 30, each current detection amplifier 51 causes the current flowing through each element 15a to be simultaneously (parallel) to each connected element 15a. To detect. Note that the details of the configuration of the current detection amplifier 51 are not related to the gist of the present invention, and thus detailed description thereof is omitted here, but various known configurations can be applied. Depending on the configuration of the current detection amplifier 51, the connection means 52, the power source 53, and the connection mode with each element may differ from the above example.
[0042]
In the radiographic imaging / reading apparatus 1 having the above-described configuration, when recording an electrostatic latent image on the detector 10, first, the connecting means 52 is switched to the power supply 53 side, and a direct current is applied between the conductor layer 11 and the stripe electrode 15. A voltage is applied to charge both. Next, recording light is blown onto a subject (not shown), and the detector 10 is irradiated with radiation (recording light) carrying radiation image information of the subject that has passed through the subject. Then, positive and negative charge pairs are generated in the recording photoconductive layer 12 of the detector 10, and the negative charges are concentrated on each element 15a of the stripe electrode 15 along a predetermined electric field distribution. The negative charges are accumulated in the power storage unit 16 that is an interface between the conductive layer 12 and the charge transport layer 13. Since the amount of accumulated negative charges (latent image charges) is substantially proportional to the radiation dose, the latent image charges carry an electrostatic latent image, and the electrostatic latent image is recorded in the detector 10. The On the other hand, the positive charge generated in the recording photoconductive layer 12 is attracted to the conductor layer 11 and recombines with the negative charge injected from the power source 53 and disappears.
[0043]
Next, when reading the electrostatic latent image from the detector 10, the connecting means 52 is first connected to the conductor layer 11 side of the detector 10, and the light source control means 40 sequentially switches the comb teeth 31a, A predetermined DC voltage is applied between each comb tooth 31 a and the conductive layer 33, and the entire surface of the detector 10 is electrically scanned with the line light emitted from the EL layer 32.
[0044]
By scanning with this line light, positive and negative charge pairs are generated in the photoconductive layer 14 on which the line light corresponding to the sub-scanning position is incident, and the positive charge therein is a negative charge (latent image charge) accumulated in the power storage unit 16. ) Rapidly move in the charge transport layer 13 so as to be attracted to the latent image charge and disappear in the power storage unit 16. On the other hand, the negative charge generated in the photoconductive layer 14 is recombined with the positive charge injected from the power source 53 into the conductor layer 15 and disappears. In this way, the negative charge accumulated in the detector 10 disappears due to charge recombination, and a current is generated in the detector 10 due to the movement of charge during this charge recombination. This current is detected simultaneously by each current detection amplifier 51 connected to each element 15a. Since the current flowing in the detector 10 at the time of reading corresponds to the latent image charge, that is, the electrostatic latent image, the electrostatic latent image is read by detecting this current, that is, represents the electrostatic latent image. An image signal can be acquired.
[0045]
By the way, in the apparatus 1 having the above-described configuration, as the detector 10, the insensitive portion a that is not sensitive to radiation is provided at both ends in the longitudinal direction of the stripe electrode 15 outside the image region S where image information can be recorded. , B are used. All the elements 15a of the stripe electrode 15 extend to the end of the detector 10 so as to correspond to the insensitive portions a and b. FIG. 2 is a plan view of the stripe electrode 15 of the detector 10 in order to show the insensitive portions a and b.
[0046]
FIG. 3 is a diagram showing a method for forming the insensitive portions a and b. As shown in FIG. 3A (same as FIG. 1C), the insensitive portions a and b are not provided with a photoconductive layer on the side where the recording photoconductive layer 12 corresponding to each element 15a is laminated. 3 may be provided with a member 17 that is not sensitive to radiation, or, as shown in FIG. 3B, the recording conductor layer 11 is covered with a member 18 having high radiation absorption such as lead, Even if the recording photoconductive layer 12 is not irradiated with the recording radiation at all or is irradiated, a minute amount of radiation is irradiated, and the corresponding power storage unit 16 is formed as a portion that hardly accumulates charges representing image information. That's fine.
[0047]
When the insensitive portions a and b are provided in this way, the waveform of the image signal output from the current detection amplifier 51 connected to each of the elements e1 to en is as shown in FIG. Outside the image region), that is, the start and end portions of the stripe electrode in the longitudinal direction (sub-scan) have voltage values corresponding to the insensitive portions a and b, and the image region portion is stored in the power storage unit 16. A signal voltage representing the radiation image information is generated according to the amount of charge.
[0048]
As described above, in the detector of the stripe electrode readout method, not only the current corresponding to the amount of charge accumulated in the power storage unit 16 corresponding to the pixel of interest irradiated with the reading light of each element, but also the attention A current corresponding to the total amount of charge stored in the power storage unit 16 corresponding to a portion other than the pixel flows into the corresponding element as a dark current. At this time, the charge accumulated in the power storage unit 16 is sequentially read out as an image signal by the sub-scanning of the reading light to the stripe electrode 15, so that it is stored in the power storage unit 16 stacked so as to correspond to each element. The total amount of charge is gradually reduced. For this reason, as shown in FIG. 4, as the image signal output from the amplifier 51, the dark current component of the insensitive portion a at the scanning start portion is larger than that of the insensitive portion b at the end portion. For the image region portion, a signal component representing image information is superimposed on the dark current component. In the insensitive part b at the end of scanning, since all the charges accumulated in the power storage unit 16 should be read out, the dark current component is hardly generated. May not be read as residual charges in the detector 10, and in this case, a dark current component corresponding to the residual charges left unread is generated, and the image signal output from the current detection amplifier 51 When the image is reproduced based on the above, an image having an increased density due to an offset due to dark current is generated.
[0049]
On the other hand, in the apparatus 1 to which the present invention is applied, as shown in FIG. 1, dark current reducing means 100 for correcting the image signal so as to reduce the dark current component included in the image signal is provided. Hereinafter, the dark current reducing means 100 will be described in detail.
[0050]
As shown in FIG. 1, the dark current reducing unit 100 connected to the current detection amplifier 51 includes a memory 110, a correction data calculation circuit 120, and a subtraction circuit 130. The image signal output from the amplifier 51 is converted into digital image data by an A / D converter (not shown), and then input to the memory 110 of the dark current reducing unit 100. Based on the image data Da of the insensitive part a corresponding to the start part of the sub-scanning and the image data Db of the insensitive part b corresponding to the end part of the sub-scanning, the correction data calculation circuit 120, According to each position in the sub-scanning direction, correction data Dh that gradually changes so as to become larger at the start portion of the sub-scan and smaller at the end portion thereof is obtained. Specifically, the gradually changing correction data Dh is, as indicated by a dotted line in FIG. 4, for each element, a sub-scanning start portion corresponding to the insensitive portion a and a sub-scanning end corresponding to the insensitive portion b. The data Da, Db of the part may be obtained by linear interpolation.
[0051]
The subtraction circuit 130 performs a subtraction process for subtracting the correction data Dh from the image data Ds of the image area S for each element. As a result, the image data Dss output from the subtraction circuit 130 is obtained as a signal with a reduced dark current component.
[0052]
If an image is reproduced based on the image data Dss in which the dark current component is reduced, an image having an appropriate density can be obtained without causing an offset due to the dark current in the reproduced and output image.
[0053]
In the above embodiment, the detector using the insensitive portion provided at both ends of all the elements of the stripe electrode has been described. However, the detector used in the present invention is not necessarily provided at both ends of all the elements. The insensitive part may not be provided. For example, among the elements e1 to en of the stripe electrode 15 shown in FIG. 2, the insensitive portions a and b are provided at both ends of the odd-numbered elements, and the insensitive portions are not provided at both ends of the even-numbered elements. It is good also as an aspect with which the parts a and b were provided every other element. Needless to say, insensitive portions a and b may be provided at both ends of every other element, not limited to every other element.
[0054]
Thus, when using the detector of the aspect which provided the dead part in the both ends of every other element or several elements, the above-mentioned dark current reduction means 100 is the element (it mentioned above). The correction data Dh in the longitudinal direction is obtained using the insensitive part data Da and Db of the insensitive element also for the even-numbered element in every other example). In this case, for each of the elements sandwiched between the elements having the insensitive part, the correction data of the element having the insensitive part may be used as the correction data of the element having no insensitive part. For example, when the correction data Dh2 for the element e2 is obtained, the correction data Dh1 for the element e1 or the correction data Dh3 for the e3 itself is used as the correction data Dh2 for the element e2.
[0055]
Further, for each of the start part and the end part of the sub-scanning, the data of each insensitive part of the element having the insensitive part is used (interpolated) according to each arrangement position of the element sandwiched between the elements having the insensitive part. ) The obtained data may be regarded as data of each insensitive part of the sandwiched element, and correction data for the element may be obtained based on this data (referred to as Method 1). For example, the data Da2 obtained by interpolation using the insensitive part data Da1 and Da3 of the scanning start part of the elements e1 and e3 is regarded as the insensitive part data of the scanning start part of the element e2, and the elements e1 and e3 The data Db2 obtained by interpolation using the insensitive part data Db1 and Db3 of the scanning end part is regarded as the insensitive part data of the scanning end part of the element e2, and the element is based on the obtained data Da2 and Db2. For example, longitudinal correction data Dh2 for e2 is obtained.
[0056]
As described above, even if the correction data is obtained based on the data of the element having the insensitive part even with respect to the element having no insensitive part, even if the insensitive part is provided in some of the elements, Correction data can be obtained.
[0057]
In the above embodiment, the detector using the insensitive portion provided at both ends of the element (all or a part) has been described. However, the detector used in the present invention is not necessarily limited to this. For example, a detector corresponding to the start part of the sub-scan and the end part of the sub-scan, that is, a detector provided with a dead part at one end of the element may be used. Not all of the elements may be the same as described for the insensitive portion provided at both ends.
[0058]
For example, in FIG. 2, when the detector is provided with the insensitive part at the start part of the sub-scan (on the side where the amplifier is connected), the dark current reducing means 100 uses the insensitive part data of the starting part a. Da is used as the correction data Dh, and the correction data Dh (= Da) is subtracted from the data Ds of the image area portion S. FIG. 5A shows an example of the image signal in this case.
[0059]
In FIG. 2, when the detector is provided with a dead portion at the end of the sub-scan (on the side where the amplifier is not connected), the dark current reducing means 100 uses the dead portion data of the end b. Db is used as the correction data Dh, and the correction data Dh (= Db) is subtracted from the data Ds of the image area portion S. FIG. 5B is a diagram showing an example of the image signal in this case.
[0060]
Even in these cases, it is assumed that the insensitive portion is provided at both ends by using the expected data value as the insensitive portion data for the end portion on which the insensitive portion is not provided. Similarly to the case where insensitive portions are provided at both ends, correction data that gradually changes so as to be larger at the start portion of the sub-scan and smaller at the end portion of the sub-scan according to the position in the longitudinal direction of each element. It may be.
[0061]
Further, in the case where the detector is provided with the insensitive part at one end of each of the stripe electrodes, it is more preferable that the one and the other are alternately arranged. Although “alternating” is used, the arrangement is not limited to one linear electrode but may be alternately arranged every several electrodes.
[0062]
In this case, the correction data for the element having the insensitive part may be obtained in the same manner as the one having the insensitive part provided on one side, but the opposite end where the insensitive part is not provided, The insensitive part is provided at both ends by regarding the insensitive part data (the data itself or interpolated data) of the element having the other adjacent insensitive part as the insensitive part data at the opposite end. Deemed (referred to as method 2), as in the case where the insensitive portions are provided at both end portions described above, the sub-scanning start portion is larger and the sub-scanning end portion is smaller, depending on the position of the stripe electrode in the longitudinal direction. It is preferable to obtain correction data that gradually changes as described above.
[0063]
Further, it is preferable to obtain correction data for the longitudinal direction of not only an element having an insensitive part at one end but also an element having no insensitive part sandwiched between elements having an insensitive part. Specifically, the above-described method 1, method 2 or other combinations may be performed, and the insensitive portion data of the element provided with the insensitive portion is used to interpolate in the arrangement direction of the elements 15a. The data may be regarded as data of each insensitive portion of the element not provided with the insensitive portion, and correction data for the longitudinal direction of the element not provided with the insensitive portion may be obtained based on this data.
[0064]
Thus, even if an insensitive part is provided for a part that does not have a dead part, if correction data is obtained based on the data of the element that has a dead part at one end, the image area Correction data for the whole can be obtained.
[0065]
In the above embodiment, the description has been given of the case where all the current detection amplifiers 51 are connected to one end side of the stripe electrode 15 of each element 15a. However, the amplifier 51 is located on either side of the element 15a. Whether they are connected does not matter when the line resistance of each element 15a is sufficiently small.
[0066]
Further, although scanning by reading light is performed by line light has been described, it goes without saying that each element may be sequentially scanned by beam light in the main scanning direction and then scanned in the sub scanning direction. When scanning with the beam light, one current detection amplifier may be provided, and the stripe electrodes may be sequentially switched and connected with a switch in conjunction with the scanning of the beam light in the main scanning direction. An amplifier may be provided.
[0067]
On the other hand, when the line resistance of each element 15a is not negligible, it is desirable to correct the variation factor of the dark current component at each position in the longitudinal direction caused by the line resistance of each element 15a. Hereinafter, this aspect will be briefly described with reference to FIG.
[0068]
First, every other element or every several elements 15a, one end and the other end of the stripe electrode 15a are repeatedly staggered so that the current detection amplifier 51 is connected to the one end or the other end of each element 15a. Connect to the end of the. In the embodiment shown in FIG. 6, the current detection amplifier 51 is connected to the insensitive part a side and the insensitive part b side for every two elements 15a. In this way, if the current detection amplifier 51 is not arranged so as to be concentrated on one side of the stripe electrode 15, but if the current detection amplifier 51 is arranged approximately equally in the vicinity of one end and the other end, the current detection amplifier 51 is provided. This is also convenient for integrating the 51 and the detector 10 together. The insensitive part may be provided on both sides of the stripe electrode 15 as shown in FIG. 6, or may be provided on only one of them.
[0069]
Each current detection amplifier 51 is connected to dark current reduction means 100 ′ having a memory 110 ′, a correction data calculation circuit 120 ′, and a subtraction circuit 130 ′.
[0070]
As in the case shown in FIG. 1, the image signal output from the amplifier 51 is converted into digital image data by an A / D converter and then input to the memory 110 ′ of the dark current reducing means 100 ′. . The correction data calculation circuit 120 ′ performs the sub-scan of each element 15a based on the image data Da of the insensitive part a corresponding to the start part of the sub-scan and the image data Db of the insensitive part b corresponding to the end part of the sub-scan. According to each position in the direction, correction data Dh that gradually changes so as to be larger at the start portion of the sub-scan and smaller at the end portion. At this time, the components Da and Db of the insensitive part of the four elements 15a are averaged for every four consecutively adjacent elements among the elements 15a. A correction component for the image signal at each position other than the dead area is obtained. For example, for the elements e1 to e4, the insensitive part data Da1 and Da2 of the scanning start part of the elements e1 and e2 and the insensitive part data Db3 and Db4 of the scanning end part of the elements e3 and e4 are used. Correction data Dh1 to Dh4 in the longitudinal direction are obtained for. The above-described processing is sequentially repeated for the other elements e5 and the like.
[0071]
The subtraction circuit 130 ′ performs a subtraction process for subtracting the correction data Dh from the image data Ds of the image area portion S for each element. As a result, the image data Dss ′ output from the subtracting circuit 130 ′ is not only reduced in the dark current component, but also reduced in the longitudinal direction due to the line resistance of the element 15a. .
[Brief description of the drawings]
FIG. 1 is a schematic view of a radiographic image capturing / reading apparatus to which a radiographic image data acquisition method and apparatus according to the present invention is applied.
FIG. 2 is a plan view showing a stripe electrode (reading electrode) of the detector.
FIGS. 3A and 3B are diagrams showing a method for forming an insensitive portion. FIGS.
FIG. 4 is a diagram illustrating an example of a waveform diagram of an image signal output from an amplifier and correction data;
FIGS. 5A and 5B are diagrams illustrating an example of a waveform diagram of an image signal output from an amplifier and correction data when a dead portion is provided at one end of an electrode; FIGS.
FIG. 6 is a schematic diagram of another embodiment of a radiographic image capturing and reading apparatus to which the radiographic image data acquisition method and apparatus according to the present invention is applied.
[Explanation of symbols]
1 Radiographic imaging reader
10 Radiation solid state detector
20 Reader
30 Planar light source
40 Light source control means
50 Current detection circuit
51 Current sense amplifier
52 Connection method
100 Dark current reduction means
110 memory
120 Correction data calculation circuit
130 Subtraction circuit
100 'dark current reduction means
110 'memory
120 'correction data calculation circuit
130 'subtraction circuit

Claims (14)

An optical readout radiation solid-state detector comprising: a power storage unit that stores an amount of electric charge corresponding to the dose of irradiated radiation; and a stripe electrode composed of a plurality of linear electrodes stacked on the power storage unit. In the radiation image data acquisition method for using and acquiring an image signal representing radiation image information from the radiation solid detector, as the radiation solid detector, the radiation is applied to a portion corresponding to a part in a longitudinal direction of the stripe electrode. A non-sensitive insensitive part is used, and the image signal is included in the image signal based on the component of the insensitive part for each linear electrode in the longitudinal direction of the stripe electrode. A radiation image data acquisition method comprising correcting components other than the insensitive portion so that dark current components are reduced. 2. The radiation image data acquisition method according to claim 1, wherein the radiation solid state detector is one in which the insensitive part is provided in an area outside the image area in the longitudinal direction of the stripe electrode. The radiation image data acquisition method according to claim 2, wherein the radiation solid state detector uses the insensitive part provided at one end of the stripe electrode. As the radiation solid detector, while using the insensitive portion provided at both ends of the stripe electrode,
Obtaining a correction component for the image signal at each position other than the insensitive portion in the longitudinal direction of the stripe electrode based on the insensitive portion components provided at both ends of the image signal;
The radiation image data acquisition method according to claim 2, wherein the correction is performed based on the correction component. As the radiation solid detector, the insensitive part is used only provided in a part of the linear electrode of the stripe electrode,
For the linear electrode not provided with the insensitive part, other than the insensitive part in the longitudinal direction of the stripe electrode based on the component of the insensitive part of the linear electrode provided with the insensitive part of the image signal 5. The radiographic image data acquisition method according to claim 3, wherein a correction component for the image signal at each position is obtained. The image signal for a part of the plurality of linear electrodes arranged in a row is acquired at one end of the stripe electrode,
6. The image signal for the remaining linear electrode among the plurality of linear electrodes arranged in series is acquired at the other end of the stripe electrode. The radiation image data acquisition method according to item. An optical readout radiation solid state detector comprising a power storage unit that accumulates an amount of electric charge corresponding to the dose of irradiated radiation, and a stripe electrode composed of a plurality of linear electrodes stacked on the power storage unit; A radiation image data acquisition apparatus comprising: a reading unit that scans the reading light in the longitudinal direction of the stripe electrode to acquire an image signal representing radiation image information . The insensitive part insensitive to the radiation is formed in a part corresponding to a part, and in the longitudinal direction of the stripe electrode in the image signal, the insensitive part component for each stripe electrode And a dark current reducing means for correcting a component other than the insensitive portion so that the dark current component included in the image signal is reduced. Over data acquisition device. The radiation solid detector is such that the insensitive part is provided at both ends of the stripe electrode,
The dark current reducing means obtains a correction component for the image signal at each position other than the insensitive portion in the longitudinal direction of the stripe electrode based on the insensitive portion components provided at both ends of the image signal, 8. The radiation image data acquisition apparatus according to claim 7, wherein the correction is performed based on the correction component. The radiation solid detector is such that the insensitive part is provided only on a part of the linear electrode of the stripe electrode,
The dark current reducing means uses the insensitive part component of the linear electrode provided with the insensitive part of the image signal for the linear electrode not provided with the insensitive part. 9. The radiographic image data acquisition apparatus according to claim 7, wherein a correction component for the image signal at each position other than the insensitive part in the longitudinal direction of the electrode is obtained. The reading unit obtains the image signal for one of the plurality of linear electrodes arranged in a row at one end of the stripe electrode, and the plurality of the consecutive electrodes arranged in a row. The radiographic image according to claim 7, wherein the image signal for the remaining linear electrodes among the linear electrodes is acquired at the other end of the stripe electrode. Data acquisition device. An optical readout solid-state detector comprising a power storage unit for accumulating an amount of electric charge corresponding to the dose of irradiated radiation and a stripe electrode composed of a plurality of linear electrodes stacked on the power storage unit. A solid-state radiation detector, wherein an insensitive part insensitive to the radiation is formed in a part corresponding to a part of the stripe electrode. 12. The radiation solid state detector according to claim 11, wherein the insensitive part is provided in a region other than a desired image region in the longitudinal direction of the stripe electrode. 13. The radiation solid state detector according to claim 12, wherein the insensitive part is provided on at least one of both end portions of the stripe electrode. A current detection amplifier connected to one end of the stripe electrode for obtaining the image signal of a part of the plurality of linear electrodes arranged in a row; And a current detection amplifier connected to the other end of the stripe electrode for acquiring the image signal of the remaining linear electrodes among the plurality of linear electrodes arranged side by side. Item 14. The solid state radiation detector according to any one of Items 11 to 13.

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